Synthesis of Taurine and N-Methyltaurine

Synthesis of Taurine and. J. N-Methyltaurine. A modified procedure for the synthesis of taurine $+a+ debeloped which utilized inexpensiT e and readily...
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INDUSTRIAL AND ENGINEERING CHEMISTRY Bruni, G., Rcc. grn. caoutchouc, 8 (75), 19 (19;31). Curtis, H. L., McPherson, A . T., and Scott. -1.H.. Ijui.. Staiidards, Sci. Paper No. 5 6 0 , 2 2 , 398 (1927). Farmer, E. H., ";idvances in Colloid Science," Vol. 11, 0. .342-4, New York, Interscience Publishers, Inc., 1943. Farmer E . H., and Shipley, F. IT.,J . Pol!jmerSci., 1, 2W ( l U i 6 i . Fisher, H . L., andSchubert, I-., ISD.ESG. CHEM.,28, 209 (19x6) Hardman. A . F., and White, F. L., Ibid., 19, 1037 (19271. Hauser and Sze, Rubber Chem. Tech., 17, 788 (11144). Henriquea, Chem.-Ztg., 17, 634 (1893); 18, 701, 11.55 (Ih!14) Hehn, J. B., Gztmmi-Ztg.. 14, 17-33 (1899). Htibener, G., Z . angew. Chem., 7 , 112, 142 (1591:. Jessup, R . A , , and Cummines, A. D., J . Rrsrrrwh Yicti. Niii.

Vol. 39, No. 7

(271 Shepard, h-..I.,and Krall, S . , Z h i L , 14, 951 (1922). (28) Sheppard, S. E . , India R i ~ b b r vn-odil. 80, S o . 2 . 56 (1929,. (29) Speiice, D.. and Young. J.. Roiioid-Z.. 11, 28 (1912): / ' h t ' r r i . Zta.. 36. 1162 11912). (30) Site&. H.. Ibid., 33, 756 ( l 9 l O i (31) Steven., H. P., J . Soc Chem. I),(/.,38, 19LT (19191.

Standards, 13, 357 (1934).

Jones and Reed, J . Am. Chem. S'oc.. 60, 2452 1,1!3:3hi. Kirkoff and Matulke, Ber., 57B, 1260 (1924). lIaxwell, R. B., and Park, C . K..1x1,. ESI-. CHEJI.,24, l i b (1932).

Messenger, T. H., T r a n s . I M ~ Rititbci, . Itid., 5, 71-% (1929): Riihher Chena. Tech., 3, 24 (19301. Meye]. andHohenemaer, ICid., 9, 201 (l!Jl(tii. Saj-lor, I{. F., J . Polymer Sci., 1, 305 (19461 0,twalil. If-.,Kolloid-Z., 6 , 136 (1910). Park. C . 13.. IXD.ESG.CHEM.,22, 1004 (1930). Saiidstroni. I < .V.,I b i d . , 25, 684, 1400 (1933). Selker, XI. L., and Kemp, A . R . , I h i d . , 36, 27 (1944): Kiit,bo. them. ~ ~ ~1 7 h, 3 0. 3 (1944). ,

Synthesis of Taurine and N-Methyltaurine J

A modified procedure for the synthesis of taurine $+a+ debeloped which utilized inexpensiTe and readily a, ailable materials. Ethjlene chloride was sulfonated with sodium sulfite and then aminated with (a)anh~drousammonia and ( b ) aqueous ammonia (27qc) and ammoniunl carbonate. % colorimetric method for the determination of minute amounts of taurine consisted of developing a blue color from the reaction of taurine +I ith a solution of phenol and calcium h,pochlorite. ,V-JIeth?ltaurine was s!nthesized bj the amination of sodium 2-chloroethane-lsulfonate with (a)anhydrous methJlamine and ( b ) aqueous methylamine (30-40q0).

T

AYKISE \vas first prepared synthetically in 1885 when James treated silver and ammonium salts of 2-chloroethane1-sulfonic acid with a n excess of ammonia ( 7 ) . Since then it has been synthesized from 2-bromoethylamine hydrochloride and metallic sulfites ( I s ) ,by decarboxylation of rysteic acid ( 1 6 ) , addition of ammonia t o vinylsulfonic arid (51, ammonolysis of isethionic acid (6, 10, 13), sulfonation of aminoalkyl sulfates n-ith alkali sulfite ( 5 ) , hydrolysis of sodium tauroglycocholate (91, and the oxidation of cystamine. It occur.< naturally in marine animals and mammals and thus has been isolated from the inuscles of fish, mollusks, and crustacea ( l d ) , as \\-ell a s from the bilr of oxen, slieep, dogs, and human beings (a). Although the synthetic methods mentioned are very good, they require st,artingmaterials that are expensive and difficult to obtain. The present investigation, carried out during the Tvar years, was conducted for the prime purpose of developing a method adapt1

Present address, Sorony-Vacuum Oil Company. I n c . , Paulsboro, li. J.

:itile tci i.iiiiiiiiercia1 pro:iuctioii utilizing tlir least costly arid rlloht readily available materials. Interest was centered upon taurine and related compounds because of their potentialitier as cheap intermediates for wetting agents and detergents ( 4 , 8 ) . AT-hlethyltaurine was synthesized hy Dittrich in 1878 nheii lit. reacted methylamine with the silver salt of 2-chloroethnnr-lsulfonic acid ( 1 ) . -1 German patent claims t h a t the sodium salt of vinylsulfonic acid can he reacted with a primary amirit,for example, methylamine-to give S-niethyltaurine ( 5 ) . A--hIethyltaurine crystallizes as prisms (melting point 24 1 2 ' C.) and is soluble in water; it is insoluble in ethyl alcohol and ethyl ether, anti does not form salts n-ith acids or bases (5). Carius tubes (200-ml. capacity) were used in bomb reac>tiiiii> for small samples, and a nickel-lined stationary autoclav? w a ~ I I . P ~ for larger samples. PKEP.AR.iTIOS O F SOUlL \1 2-CHLOHOE:TH.i\ k;l-SZTLFOS41'E (12)

Oiir tiunilrrcl grams of ethylencb cliloride (1.0 mole) :trid 126 griiniz~of ailhydrous sodium sulfite (1.0 mole) were heated under

reflux in a 2-liter three-necked flask equipped with a mechanical .tirrer and an efficient condenser, with 530 grams of n-ater and 400 grams of ethanol i n the presence of copper turnings. (The copper turnings act nut only as a catalyst but also as :in aid t o efficient stirring.) After refluxing for 72 hours, a Cigreus fraction:iting column {vas substituted for the condenser, and t h e Icnction mixture \vas distilled. The first fraction (boiling point 72" C.) contniiied 8 . 3 q water and 9 1 . 7 5 et,hylene chloride. Tile secpnd fraction (boiling point 73-95' C.) contained ethanol and water. The combined fractions xvere utilized in the nest batch reaction. The aqueous residue from the distillation xvas evaporated to dryness on a steam bath. T h e resultant salt cake had a motherof-pearl li~qter. The impure salt \ ~ R Pground in a mortar, and

INDUSTRIAL AND ENGINEERING CHEMISTRY

July 1947

907

Figure 1. JIaterials Cost' and Flow Sheet for Taurine Production

=

n

252 grams NarSO:, 0.03 Ib.

200 grams CI CH2.CHi.CI. 0 085 Ib.

086

I

Cu Fon

~ O U I U NST-LFITE:

261'. X 4 . 6 X 0 . 0 3 4,54

=

n

I

1000 ml.

E C O H +~

72-hr. reflux I

CI. CH:, CH1. CI, EtOH

077

.~ L (50% CI CH,. CH,' CI recovered,

C1 .CHI. CHI. 801. Na, HIO. NarBOi. NaCl

.

Evaporate to dryness C ~ . C H I . C H S . S O : N ~NaXSOr, , NaCl (assume 50% conversion)

Appror. 400 grama salt or 175 grams 7 0 4 5 % CI. CH:. CHz.SOiKa I

18 X 4 . 6 X 0.045 =

o,ol(!

looo C.

4.54

6 hr.

i

18 grams NHi(CuzCIz), 0 . 0 4 5 Ib. (tank car);

excess NHi recovered

HsN CHr .CHI. S o d a , 2000 ml. (1670 grams)

HC1 (EtOH recoverable), 0 0175 Ib. HSN"~HI.CHI,SO:H

1670 X 0.0175 - 0. 06D 4.54

ToTar,, 0 . 2 3 8

98.3 grams (assume 75% conversion)

Prire on bn-is of 1 pound of taurine: 454'98.3 = 4 . 6 factor. o f a l c o h o l is not inrluded because it is recoverable.

' Cost

the puwdw was estrncted with hot 95", ethanol in a Soxhlet extractor. 11-hite platelets were filtered and dried. The product weighed 130 grams: this indicated a 78% conversion of the ethylene chloride. Sulfur analysis of CI C:H,SO,Na : experimentnl. 19.08%: calculated, 19.10C;. I'REPAN i'rlON O F TAtiRINE

. One hundred twenty-t,a-o grams of etlinnolamine (2.0 moles) \\-ere cooled in a n ice bath and carefully neutralized with concentrated hydrochloric acid. After complete neutralization a slight escess of hydrochioric acid n-as added, and the solution rras evaporated to a viscous liquid which crystallized when allon-ed t o cool. Sinety-sis grams of the ethanolamine hydrochloride (1.0 mole) were suspended in 200 ml. of chloroform nnd placed in a 500-ml. three-necked flask equipped with a nieclianical stirrer, condenser, and dropping funnel. One hundred fifty-eight grams of thionyl chloride ( 3 3 5 escess) in 100 ml. of chloroform were added dropwise. The suspended ethanolamine hydrochloride seemed to disappear n-ith the voluminous evolution of hydrogen chloride. hfter evolution of the hydrogen chloride hnd ceased, the chloroform \vas removed under diminished pressure. The crystalline product (n1.p. 140' C., conversion SOc;) was extracted vitli amyl alcohol. Fifty grams of the 2-chloroethylaniine hydrochloride (0.43 mole), dissolved in 200 ml. of water, wwe added t o 91 grams of sodium bisulfite (0.86 mole) and heated strongly under reflux for approsimately 6 hours. The solution vas evaporated under diminished pressure until n nhite crystalline residue was obtained. This residue w a ~t l i o ~ ~ ~ u g l niised ily with 250 ml. of concentrated hydrochloric acid. The precipitated salts were filtered and washed several times n-ith small portions of concentrated hydrochloric acid. The filtrate !!-as coiicentrated to 200 ml., and 150 ml. of 9 5 s ethanol were added to the hot solution. Twenty-eight grams (51Yc of a 11-hite needlelike product, taurine) were obtained upon cooling tlit eolution. Sodium sulfite \vas substituted for sodium bisulfite, and 20 grams (40%) of taurine (2-aniinoetliaiie-1-siilfonic acid) were ohtained. .lmrosoI,yaIs WITH . ~ H I . D R O V S A \ ~ n ~ o s ~Ten . i . grams of sodium 2-cliloroet~liane-1-sulfonate (0.06 mole) and 20 grams of anhydrous ammonia (1.8 moles) were sealed in a Carius tube (200-ml. capacity) and subjected t o a temperature no higher than 50" C. for four days. The tube \vas carefully opened and the ~ T H . ~ S O L A M I S1'ROC E

excess ammonia permitted t o escape. The solid residue wm treated with approximately 100 ml. of concentrated hydrochloric acid. T h e insoluble salts were filtered, and the filtrate was evaporated t o one third its original volume. Four volumes of 95% ethanol were added, and the solution was set aside to crystallize. Small needlelike crystals of taurine weighing 3.47 grams (47%) were obtained. The product was further purified by dissolving in five times its weight of hot water and then crystallized by the addition of four volumes of 9 5 q ethanol. Time of contact and temperature appeared t o be important factors in determining the conditions for optimum yield